Top 5 robot trends in 2021

Published
April 08, 2021 - 05:15am
Top 5 robot trends in 2021

Five trends have helped triple the number of annual installations of industrial robots within ten years (2010-2019) reaching 381 thousand units in factories around the world, according to the International Federation of Robotics.

“The mission to combine traditional production with ´go digital strategies´ puts robots in a pole position,” said Dr Susanne Bieller, General Secretary of the IFR.

Here are the top 5 trends shaping industries around the globe.

1.    Robots learn new tricks: Artificial intelligence software in combination with vision and other sensing systems, allow robots to master difficult tasks. One such task is bin picking, that in the past was only feasible for a human hand. New generations of robots are easier to install and program and they are connectable. Advances in communication protocols integrate robots seamlessly into automation and Industry 4.0 strategies. 

2.    Robots work in smart factories: The automotive industry pioneered smart factory solutions utilizing industrial robots throughout assembly lines that have dominated traditional automobile production for more than 100 years. The future belongs to networked interaction of robots and autonomous guided vehicles - or rather autonomous mobile robots (AMRs). Equipped with the latest navigation technology, these mobile robots are much more flexible compared to traditional production lines. Car bodies are conveyed on driverless transport systems. They can be decoupled from the assembly line flow and redirected to assembly stations where individually equipped variants can be assembled. When models are changed completely, it is only necessary to reprogram the robots and AMRs rather than to dismantle the entire production line. With the integration of human-robot collaboration workstations picking up momentum, robot suppliers report robots working hand-in-hand with humans without fencing.

3.    Robots enter new markets: The connectivity breakthroughs contribute to increased robot adoption in manufacturing sectors that have only recently turned to automation, such as food and beverage, textiles, wood products and plastics. Ongoing digital transformation will lead to completely new business models, because producers can diversify more easily than ever. In the smart factory, different products are assembled subsequently by the same equipment - the traditional production line no longer exists.

4.    Robots reduce carbon footprint: Investments in modern robot technology will also be driven by the requirement for a smaller carbon footprint. Modern robots are energy-efficient, thus directly reducing energy consumption of production. Through higher precision, they also produce fewer rejections and substandard goods, which has a positive impact on the ratio of resource input over output. In addition, robots help in the cost-efficient production of renewable energy equipment, such as photovoltaics or hydrogen fuel cells.

5.    Robots help to secure supply chains: The pandemic situation has made the weakness of globalized supply chains visible. Manufacturers have the opportunity to rethink supply with a completely different outlook. When productivity is leveled through automation, manufacturers have increased flexibility that may not have been available in high-wage countries like most of the European Union, North America, Japan or the Republic of Korea. Robotic automation offers productivity, flexibility and security.

“Advances in robot technologies are contributing to increased robot adoption,” says Dr Susanne Bieller, General Secretary of the IFR. “The COVID-19 pandemic hasn`t started any new trends but it accelerated the use of robotics beyond established practice. In this respect, the pandemic has proven to be the biggest single driver for change in industry.”

For more trends on the global robotics market please visit IFR´s website at https://ifr.org/

Related Glossary Terms

  • robotics

    robotics

    Discipline involving self-actuating and self-operating devices. Robots frequently imitate human capabilities, including the ability to manipulate physical objects while evaluating and reacting appropriately to various stimuli. See industrial robot; robot.

  • shaping

    shaping

    Using a shaper primarily to produce flat surfaces in horizontal, vertical or angular planes. It can also include the machining of curved surfaces, helixes, serrations and special work involving odd and irregular shapes. Often used for prototype or short-run manufacturing to eliminate the need for expensive special tooling or processes.

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